Combined Lectures 16-24 PDF

Summary

These lectures cover photosynthesis in detail, including the chemical equation, stages, key components (chloroplasts, thylakoids, stroma, chlorophyll), autotrophs vs. heterotrophs, and the relationship to cellular respiration. Concepts like the electromagnetic spectrum, pigments, and photosystems are also examined.

Full Transcript

Photosynthesis Overview

What is Photosynthesis? Photosynthesis is the process by which green plants, algae, and some
bacteria convert light energy into chemical energy, producing glucose and oxygen from carbon
dioxide and water.

Chemical Equation: The overall equation for photosynthesis is:
6CO2+6H2O→C6H12O6+6O26CO_2 + 6H_2O \rightarrow C_6H_{12}O_6 + 6O_26CO2+6H2O→C6
H12O6+6O2

Stages of Photosynthesis

1. Light-Dependent Reactions:

o Location: Thylakoid membranes in chloroplasts.

o Process:

▪ Capture sunlight using chlorophyll.

▪ Convert light energy into ATP and NADPH.

▪ Water molecules are split, releasing oxygen as a byproduct.

2. Light-Independent Reactions (Calvin Cycle):

o Location: Stroma of chloroplasts.

o Process:

▪ Utilize ATP and NADPH to convert CO2 into glucose through a series of
reactions known as carbon fixation.

Key Components

Chloroplasts: Organelles where photosynthesis occurs; contain thylakoids and stroma.

Thylakoids: Membrane-bound structures within chloroplasts where light-dependent
reactions take place.

Stroma: Fluid surrounding thylakoids; site of light-independent reactions.

Chlorophyll: Pigment that captures light energy; primarily absorbs blue-violet and red light.

Autotrophs vs. Heterotrophs

Autotrophs (e.g., Plants): Organisms that produce their own food through photosynthesis.

Heterotrophs (e.g., Humans): Organisms that consume other organisms for food.

Opposites in Respiration

The products of photosynthesis (glucose and oxygen) are the reactants of cellular
respiration, and vice versa.
Electromagnetic Spectrum

Visible Light Spectrum: Wavelengths between 400-700 nm are visible to humans;
chlorophyll reflects green light while absorbing other wavelengths.

Importance of Pigments

Pigments: Molecules that absorb specific wavelengths of light. Different pigments allow
plants to capture more of the sun’s energy.

Chlorophyll a and b: The primary pigments involved in photosynthesis, with chlorophyll a
being crucial for the light-dependent reactions.

Concept Check Questions

1. Autotroph vs. Heterotroph:

o Autotrophs produce their own food through photosynthesis, while heterotrophs
obtain energy by consuming other organisms. Their connection lies in the energy
flow within ecosystems.

2. Chloroplast Diagram:

o A chloroplast consists of an outer membrane, inner membrane, thylakoids (stacked
in grana), and stroma. Light-dependent reactions occur in the thylakoids, while
light-independent reactions occur in the stroma.

3. Importance of Chloroplasts:

o Chloroplasts are vital for converting solar energy into chemical energy stored in
glucose, supporting life on Earth.

4. Thylakoid Function:

o Thylakoids are where the light-dependent reactions occur; they contain chlorophyll
and are integral in capturing light energy.

5. Function of Chlorophyll:

o Chlorophyll absorbs light energy, exciting electrons that initiate the electron
transport chain, ultimately leading to ATP and NADPH production.

6. Steps in Photosynthesis:

o Capture light energy → Water splitting (light-dependent reactions) → Produce ATP
and NADPH → Convert CO2 into glucose (Calvin cycle).

Final Thought

The process of photosynthesis is essential not only for the plants but for all life on Earth, as it forms
the basis of food chains and oxygen production.

Light and Photosynthesis
Light and Pigments

Light: Electromagnetic radiation visible to plants, primarily in the wavelengths of 400-700
nm.

Pigments: Molecules that absorb light. Key pigments in plants include:

o Chlorophyll a: Main photosynthetic pigment; absorbs blue-violet light and reflects
blue-green.

o Chlorophyll b: Accessory pigment; absorbs red-blue light and reflects yellow-
green.

o Carotenoids: Accessory pigments; absorb blue-purple light and reflect orange.

o Xanthophyll: Accessory pigments; absorb blue-purple light and reflect yellow.

Chlorophyll and Photosystems

Chlorophyll Structure: The shape of chlorophyll determines the wavelengths it absorbs
and reflects. Chlorophyll a reflects bluish-green light, while chlorophyll b, with a slight
structural change, reflects more yellow light.

Photosystems: Complexes of pigments (including chlorophyll) and proteins located in the
thylakoid membranes. They capture light energy and excite electrons. Two types:

o Photosystem II (PSII): Absorbs light at 680 nm (P680); splits water to replace
electrons.

o Photosystem I (PSI): Absorbs light at 700 nm (P700); accepts electrons from the
electron transport chain.

Light-Dependent Reactions

Location: Thylakoid membranes in chloroplasts.

Process:

o Photon Absorption: Light energy is absorbed by chlorophyll, exciting electrons.

o Electron Transport Chain (ETC): Excited electrons are transferred through a series
of proteins, generating a proton gradient (H+).

o ATP and NADPH Production: H+ ions flow back through ATP synthase, creating ATP.
Electrons reduce NADP+ to form NADPH.

Inputs and Outputs:

o Inputs: Light, water (H2O).

o Outputs: Oxygen (O2), ATP, NADPH.

Calvin Cycle (Light-Independent Reactions)
 Location: Stroma of chloroplasts.

Process:

o Carbon Fixation: CO2 is incorporated into ribulose bisphosphate (RuBP) using the
enzyme RuBisCO.

o Reduction Phase: ATP and NADPH from light-dependent reactions are used to
convert 3-phosphoglycerate (3-PGA) into glyceraldehyde-3-phosphate (G3P), a
precursor to glucose.

o Regeneration Phase: Some G3P molecules are used to regenerate RuBP, allowing
the cycle to continue.

Inputs and Outputs:

o Inputs: CO2, ATP, NADPH.

o Outputs: G3P (sugar precursors).

Role of Chemiosmosis

Chemiosmosis: The process by which H+ ions flow down their concentration gradient
through ATP synthase, driving the conversion of ADP and inorganic phosphate (Pi) into ATP.
This process is crucial in both light-dependent reactions and cellular respiration.

Concept Check Questions

1. Describe light, pigments, chlorophyll (properties, function):

o Light is electromagnetic radiation that plants utilize. Pigments absorb specific
wavelengths; chlorophyll a is the main pigment, while chlorophyll b and carotenoids
assist in capturing a wider range of light energy.

2. Compare components of light-dependent and light-independent reactions:

o Light-Dependent: Occurs in thylakoids, requires sunlight, produces ATP and
NADPH, and releases O2.

o Light-Independent (Calvin Cycle): Occurs in the stroma, does not require sunlight
directly, uses ATP and NADPH to synthesize sugars.

3. Describe a photosystem and its role:

o A photosystem is a complex of pigments and proteins that captures light energy and
excites electrons for the electron transport chain, facilitating ATP and NADPH
production.

4. Explain the role of chemiosmosis in photosynthesis:

o Chemiosmosis generates ATP by utilizing the proton gradient created during
electron transport, allowing H+ ions to flow through ATP synthase.
 5. Describe inputs and outputs of light-dependent vs light-independent reactions:

o Light-Dependent: Inputs: Light, H2O; Outputs: ATP, NADPH, O2.

o Light-Independent: Inputs: CO2, ATP, NADPH; Outputs: G3P (sugar precursors).

Overview of Cellular Energy Processes

ATP (Adenosine Triphosphate)

Usage: A human at rest uses about 45 kg (99 lbs) of ATP daily but typically has a surplus of
less than 1 gram at any given moment.

Production: Each cell generates and consumes approximately 10 million molecules of ATP
per second.

Structure: ATP is an RNA nucleotide consisting of:

o Adenine

o Ribose (sugar)

o Three phosphate groups

Function: ATP acts as the energy currency of the cell, allowing for the transport and storage
of energy to support endergonic (energy-consuming) reactions. When ATP is used, it can
lose one or two phosphates, forming ADP (adenosine diphosphate) or AMP (adenosine
monophosphate).

Fermentation

Process: Fermentation begins with glycolysis, generating 2 ATP and reducing NAD+ to
NADH. In the absence of oxygen, NADH is oxidized back to NAD+ to continue glycolysis.

Types:

o Lactic Acid Fermentation: Pyruvic acid from glycolysis is converted to lactic acid
and NAD+. This occurs in muscle cells and some bacteria (e.g., yogurt production).

o Alcoholic Fermentation: Pyruvic acid is converted to ethanol and carbon dioxide,
primarily performed by yeasts and some bacteria.

Redox Reactions

Definition: Oxidation-reduction (redox) reactions involve the transfer of electrons between
compounds.

o Oxidation: Loss of electrons.

o Reduction: Gain of electrons.

Importance: These reactions are crucial for energy production in cellular respiration and
photosynthesis.
Electron Transport Chain (ETC)

Location: In cellular respiration, it occurs in the inner mitochondrial membrane; in
photosynthesis, in the thylakoid membrane.

Function: The ETC consists of a series of proteins and organic molecules that pass
electrons in energy-releasing steps, creating an electrochemical gradient (proton gradient)
that is used to produce ATP through chemiosmosis.

Comparison of Cellular Processes

Aerobic vs. Anaerobic Respiration

Aerobic Respiration: Uses oxygen, producing approximately 38 ATP per glucose molecule.

Anaerobic Respiration (Fermentation): Produces only 2 ATP per glucose molecule,
utilizing processes like lactic acid or alcoholic fermentation.

Chemiosmosis

Definition: The movement of protons across a membrane, generating ATP.

In Cellular Respiration: Protons are pumped from the mitochondrial matrix to the
intermembrane space, creating a gradient that drives ATP synthase.

In Photosynthesis: Protons accumulate in the thylakoid lumen, and ATP is generated as
they flow back into the stroma through ATP synthase.

Photophosphorylation vs. Oxidative Phosphorylation

Similarities:

o Both involve an electron transport chain and the creation of a proton gradient that
drives ATP synthesis through ATP synthase.

Differences:

o Source of Electrons: Water in photosynthesis vs. NADH/FADH2 in oxidative
phosphorylation.

o Direction of Proton Pumping: Into the thylakoid space for photosynthesis vs. out of
the mitochondrial matrix for oxidative phosphorylation.

o Terminal Electron Acceptor: NADP+ in photosynthesis vs. O2 in oxidative
phosphorylation.

Key Questions

1. Describe oxidation-reduction reactions and their importance:

o Redox reactions are essential for transferring energy through electron transfers in
cellular respiration and photosynthesis, enabling ATP production.

2. Explain why photosynthesis is endergonic and cellular respiration is exergonic:
 o Photosynthesis requires energy input (endergonic) to convert CO2 and water into
glucose, while cellular respiration releases energy (exergonic) by breaking down
glucose.

3. Compare the electron transport chain and chemiosmosis in cellular respiration and
photosynthesis:

o Both processes involve a chain of proteins transferring electrons, generating a
proton gradient to drive ATP synthesis. The main difference lies in the source of
electrons and the location of the processes.

4. Describe the generation of oxygen in photosynthesis and water in cellular respiration:

o In photosynthesis, oxygen is produced from the splitting of water molecules during
the light-dependent reactions. In cellular respiration, water is formed when
electrons combine with oxygen and protons at the end of the ETC.

5. Compare NAD+ and NADH; NADP+ and NADPH:

o NAD+ is the oxidized form; NADH is the reduced form (carries electrons). Similarly,
NADP+ is the oxidized form for photosynthesis, while NADPH is the reduced form
used in the Calvin cycle.

Here’s a summary of the key points about cell division and the cell cycle:

Cell Growth Limits

Diffusion: Effective over short distances but inefficient for larger organisms, preventing
them from being one giant cell.

Cell Division

Purpose: Essential for growth, development, and injury repair.

Types of Division:

o Mitosis: Asexual division resulting in two identical daughter cells, important for
growth and repair.

o Meiosis: Produces haploid gametes for sexual reproduction, contributing to genetic
variation.

Cell Division Rate

Cells divide at different rates. For example, gut lining cells divide constantly, while skin cells
are replaced approximately every 28-40 days.

Chromatin vs. Chromosomes

Chromatin: Unwound DNA present during normal cell function.

Chromosomes: Condensed DNA present during cell division.
Prokaryotic vs. Eukaryotic Cell Division

Prokaryotes: Divide via binary fission (asexual, identical cells).

Eukaryotes: Use mitosis (asexual, identical cells) and meiosis (sexual, genetically diverse
cells).

Advantages/Disadvantages of Reproduction

Asexual:

o Pros: Many offspring, low energy.

o Cons: Little genetic variation.

Sexual:

o Pros: Unique offspring, higher adaptability.

o Cons: Fewer offspring, higher energy requirement.

Eukaryotic Cell Cycle

1. Interphase:

o G1 (Gap 1): Cell growth and organelle synthesis.

o S (Synthesis): DNA replication.

o G2 (Gap 2): Final preparations for mitosis.

2. M-phase (Mitotic):

o Involves mitosis (nuclear division) and cytokinesis (cytoplasm division).

o Phases of Mitosis:

▪ Prophase: Chromosomes condense, nuclear envelope breaks down.

▪ Metaphase: Chromosomes align at the metaphase plate.

▪ Anaphase: Sister chromatids separate.

▪ Telophase: Nuclear envelopes reform around chromosomes.

G0 Phase

Cells can exit the cycle into a quiescent state (G0), remaining inactive until signaled to re-
enter the cycle.

Checkpoints in the Cell Cycle

G1 Checkpoint: Checks for DNA damage and conditions for division.

G2 Checkpoint: Ensures DNA is replicated and undamaged.
 M Checkpoint: Confirms all chromosomes are properly attached to the spindle.

Cytokinesis

Animal Cells: Cleavage furrow pinches the cell.

Plant Cells: A cell plate forms, leading to a new cell wall.

Ploidy

Somatic Cells: Diploid (2n), containing two sets of chromosomes.

Gametes: Haploid (1n), containing one set of chromosomes.

Concept Check

Differentiate between binary fission, mitosis, and meiosis.

Compare asexual and sexual reproduction.

Explain the stages of the cell cycle and mitosis.

Discuss haploid vs. diploid cells and their relation to cell division.

Describe cytokinesis in plant and animal cells.

Understand the role of checkpoints in the cell cycle.

Here’s a comprehensive overview of the key concepts related to DNA in eukaryotes, meiosis, and
sexual reproduction:

DNA in Eukaryotes

Location: Found in the nucleus.

Structure: DNA is wound around histone proteins, forming chromatin (loose, active form)
and chromosomes (tight, condensed form during cell division).

Chromatid: A single strand of DNA; two chromatids form a chromosome, connected at the
centromere.

Chromosomes and Homologous Chromosomes

Homologous Chromosomes: A pair of chromosomes (one from each parent) with the
same gene sequence, chromosomal length, and centromere position.

Human Chromosomes: 46 total chromosomes (22 pairs of autosomes + 1 pair of sex
chromosomes, X or Y).

Mitosis vs. Meiosis

Mitosis:

o Type: Asexual reproduction.
 o Process: DNA replication leads to the formation of two identical diploid cells (2n).

o Outcome: Sister chromatids separate.

Meiosis:

o Type: Sexual reproduction.

o Process: Two rounds of division produce four genetically diverse haploid cells (1n).

o Stages:

▪ Meiosis I: Separates homologous chromosomes, leading to genetic
reduction.

▪ Meiosis II: Separates sister chromatids, similar to mitosis.

Genetic Variation in Meiosis

Crossing Over: Occurs during prophase I when non-sister chromatids exchange genetic
material, creating new allelic combinations.

Independent Assortment: During metaphase I, homologous pairs orient randomly,
resulting in diverse gametes.

Gametogenesis

Spermatogenesis: Meiosis produces four equal sperm cells.

Oogenesis: Meiosis produces one egg and three polar bodies (unequal distribution of
cytoplasm).

Zygotes and Chromosomes

Zygote Formation: Fusion of haploid sperm (1n) and egg (1n) during fertilization forms a
diploid zygote (2n).

Karyotype: A visual representation of an individual's complete set of chromosomes,
arranged in numerical order.

Sexual Reproduction Diagram

Terms to Complete the Diagram:

o Meiosis

o Fertilization

o Haploid

o Diploid

o Egg (n)

o Sperm (n)
 o Ovary (produces egg)

o Testis (produces sperm)

o Zygote (2n)

o Multicellular diploid adults (2n = 46)

Learning Objectives

Meiosis Steps: Understand the process and purpose, including crossing over.

Chromatid vs. Homologous Chromosomes: Identify where they are in meiosis.

Zygote vs. Gamete: Understand formation processes.

Mitosis vs. Meiosis: Compare DNA replication and ploidy.

Crossing Over: Explain its significance for genetic diversity.

Germ-Line Cells: Understand their role in gametogenesis.

Chromosome Duplication and Separation: Describe the processes in both mitosis and
meiosis.

DNA Structure and Function

Euchromatin vs. Heterochromatin:

o Euchromatin: Loosely wound DNA, transcriptionally active.

o Heterochromatin: Tightly wound DNA, not transcriptionally active.

DNA Replication and Mutations

Mutations:

o Somatic cell mutations are not passed to offspring.

o Gamete mutations can be inherited.

Genetic Disorders

Trisomy 21: Three copies of chromosome 21, leading to developmental issues; an
autosomal disorder.

Twins

Identical (Monozygotic): One fertilized egg splits into two.

Fraternal (Dizygotic): Two separate eggs fertilized by different sperm.

Genetic Variation

Crossing Over: Occurs during prophase I of meiosis, leading to genetic variation.
 Independent Assortment: Homologous chromosomes orient randomly during metaphase
I, increasing diversity.

Mendelian Genetics

Mendel's Experiments: Demonstrated dominant and recessive traits using pea plants.

Genotype vs. Phenotype:

o Genotype: Genetic makeup (e.g., Aa, AA, aa).

o Phenotype: Observable traits (e.g., tall, short).

Types of Dominance

Complete Dominance: One trait masks another (e.g., violet over white flowers).

Incomplete Dominance: Blending of traits (e.g., red and white flowers producing pink).

Codominance: Both traits are fully expressed (e.g., AB blood type).

Inheritance Patterns

Multiple Alleles: More than two allele options for a gene (e.g., ABO blood types).

Polygenic Traits: Traits controlled by multiple genes (e.g., height, skin color).

Sex-Linked Traits: Traits associated with genes on sex chromosomes (e.g., color
blindness).

Test Cross

Used to determine if an organism with a dominant phenotype is homozygous or
heterozygous by crossing it with a homozygous recessive organism.

Probability in Genetics

Product Rule: Probability of multiple independent events occurring together.

Sum Rule: Probability of either of multiple mutually exclusive events occurring.

Advanced Concepts

Pleiotropy: One gene influences multiple traits (e.g., cystic fibrosis).

Epistasis: One gene masks the expression of another.

Blood Types

Universal Donor: O type (no antigens).

Universal Recipient: AB type (no antibodies against A or B antigens).

Heterozygote Advantage
 The condition where heterozygous individuals have a survival advantage (e.g., sickle-cell
trait provides malaria resistance).

Healthy Carriers

Definition: Healthy carriers are individuals who possess one copy of a recessive allele for a genetic
disorder but do not exhibit symptoms of the disorder themselves. They are often heterozygous (Aa),
where "A" is the dominant allele and "a" is the recessive allele.

Recessive Disorders

Example: Cystic Fibrosis

Genotypes:

o Carriers: Aa (healthy)

o Affected: aa (has the disorder)

Inheritance Odds for Carrier Parents (Aa x Aa):

o 25% chance of having an affected child (aa)

o 50% chance of having a healthy carrier child (Aa)

o 25% chance of having a healthy child without the allele (AA)

Carrier with Affected Individual (Aa x aa):

50% chance of being a healthy carrier (Aa)

50% chance of having the disorder (aa)

Dominant Disorders

Examples: Huntington's disease, achondroplastic dwarfism, polydactyly.

Individuals with one dominant allele (Aa or AA) express the disorder.

If one parent has a dominant disorder (Aa) and the other is unaffected (aa):

o 50% chance of inheriting the disorder (Aa)

o 50% chance of being normal (aa)

Mendel’s Laws

1. Law of Independent Assortment: Chromosomes align randomly during meiosis, leading to
different combinations of alleles.

2. Law of Segregation: During gamete formation, alleles for each gene segregate from each
other.

Test Cross
 Purpose: To determine the genotype of an individual showing a dominant trait.

Involves breeding the individual with a homozygous recessive individual to observe
offspring.

Monohybrid and Dihybrid Crosses

Monohybrid Cross: Involves one trait (e.g., YY x yy).

o F1 Generation: All heterozygous (Yy).

o F2 Generation: 3:1 ratio (3 yellow: 1 green).

Dihybrid Cross: Involves two traits (e.g., AaBb x AaBb).

o Use FOIL method to determine possible gametes.

Genetic Interactions

Pleiotropy: One gene affects multiple traits.

Epistasis: One gene masks or modifies the expression of another.

Pedigree Analysis

A diagram showing the inheritance of traits in a family across generations. It helps identify
carriers and affected individuals.

X-Inactivation

Occurs in female mammals to balance gene dosage between XX females and XY males.

One X chromosome is randomly inactivated, forming a Barr Body.

In tortoiseshell cats, this results in a mix of orange and black fur due to X-linked fur color
genes.

Genetic Variation

Causes: Mutations, random mating, fertilization, crossing over, independent assortment.

Important for adaptation and survival of populations.

Nondisjunction

The failure of chromosomes to separate properly during cell division, leading to an
abnormal number of chromosomes (e.g., trisomy).

Sex-Linked Inheritance

X-linked disorders are more common in males since they have only one X chromosome.
Males inherit X-linked traits from their mothers.

Concept Check
1. Test Cross vs. Dihybrid Cross: A test cross reveals an individual's genotype by crossing
with a homozygous recessive. A dihybrid cross examines two traits simultaneously.

2. X Inactivation Importance: It equalizes gene expression between sexes and prevents
overexpression of X-linked genes in females.

3. Calico Cats: Almost always female due to X-linked color genes and random X inactivation.

4. Somatic vs. Sex-Linked Mutations: Somatic mutations occur in non-germline cells; sex-
linked mutations affect genes on sex chromosomes.

5. X-Inactivation Explanation: It occurs to balance gene dosage between sexes and is stable
in subsequent cell generations.

6. Mendel’s Laws Connection to Meiosis: They explain how genes segregate and assort
independently during gamete formation.